FI77123C - Flow regulator - Google Patents

Description

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FLOW CONTROL

The invention relates to a flow controller with which, without auxiliary energy, the flow of liquid, vaporous and gaseous substances can be controlled independently of the inlet and outlet pressures (pressure difference) with sufficient accuracy.

5 Controllers developed for this purpose are already known. The disadvantages of these flow controllers are that the pressure difference generated by the flow in the measuring orifice without intermediate gain affects the member whose throttle varies so that the flow remains sufficiently accurately at the desired value (U.S. Pat. Nos. 2,800,919, 307,442 and 3,926,213 to German Pat. , German application publications 2747172 and 2365679 and a Finnish patent application 20 August 1973, Seppo Maijanen). The flow controller of the invention of U.S. Patent No. 15,436,409 uses hydraulic auxiliary energy, so it differs substantially from the self-powered flow controller of the present invention.

The flow controller according to the present invention is characterized in that its operation is based on a self-powered servo amplifier, as a result of which only very small disturbance forces are applied to the measuring element, which detects changes in the flow. In this case, the measuring element can be constructed in a cost-effective manner in terms of pressure difference, manufacture, long-term use and maintenance needs.

More specifically, what is characteristic of the present invention is what is stated in claims 1 and 2.

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The accompanying drawing shows a schematic vertical section of a flow regulator according to the invention. The controller consists of a measuring chamber (9) and a control chamber (10) belonging to a fixed frame. The controller can also be equipped with the display part (11).

Inside the measuring chamber 9, a choke (1), a membrane-like member (3) or a float-like member (3), a spring (2) and a spindle member (4) transmitting the movement of the membrane (3) can be placed in a known manner.

Inside the adjustment chamber (10) there is a membrane-like (pictured) or floating groove-like member (6), an opening (7) which varies as this member moves, a spring (8) and a variable distance between the spindle member (4) and the membrane-like member (6). opening (5). The opening (5) may alternatively be in a fixed body-15 part (10), whereby its throttling effect depends exclusively on the position of the ground-like spindle member (4). The sample part (11) is not essential to the invention.

20 Operating principle.

The value of the setpoint, ie the desired flow, is set by changing the throttle (1) in a known manner. A flow-dependent pressure difference occurs in the throttle (1). Said pressure difference 25 in turn generates a force in the membrane-like member (3) according to the laws of physics, which is counteracted by the spring force of the spring (2). As the flow increases, the membrane tends to move so that the spring force increases. This movement is transmitted by means of the spindle member (4) to the opening (5) of the aperture (5) - membrane (6) combination acting as a servo amplifier, so that when the spindle member (4) moves in the flow direction, the constriction caused by the opening (5) increases, and at the same time the resulting pressure difference increases. This pressure difference creates a force in the membrane-like member (6) which tends to move it in the direction of the flow 35 and to reduce the control opening (7). The orifice (7) narrows until the flow is such that the force of the spring (2) and the force caused by the flow-dependent pressure difference in the membrane-like member (3) are in balance. The invention is characterized in that the reinforcing member acts as a self-powered servo amplifier 40 and makes the position of the part closing the adjustment opening (7) of the member (6) follow the changes in the position of the member (3) without the adjustment opening (7), spring (8) and the disturbing forces caused by the member (6) affect the measuring members (2) and (3).

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Advantages of the invention.

In the same direction as the force of the film-like member (6), the force exerted on the part (6) closing said opening caused by the pressure difference in the opening (7) also acts. The latter force is at its maximum when the pressure difference P1-P2 across the regulator and at the same time also the pressure difference across the opening (7) is at its maximum. It follows that the pressure difference across the member (6) is at a minimum when the pressure difference P1-P2 is at its maximum and, conversely, the pressure difference across the member (6) is at a maximum when the pressure difference P1- P2 is at its lowest. Correspondingly, the force applied to the measuring element (3) through the closing element (4) of the opening (5) is at its lowest when the pressure difference P1-P2 acting over the regulator is at its largest and vice versa. This is a different phenomenon than previously known self-powered flow controllers.

Thanks to the solution according to the invention, the flow regulator can be made simply and reliably such that the force acting on the measuring element due to the variation of the pressure difference acting over the regulator is very small in the entire operating range. In addition, thanks to the amplifier element (6), a very small pressure difference can be used with the measuring element (3), whereby the opening (1) can be correspondingly large. This has the advantage of counteracting the risk of clogging caused by the debris 30 and of reducing the change in the value of the setpoint caused by contamination accumulating in the opening in long-term use. In addition, due to the smaller pressure difference required in the measurement, it is possible to simply apply the known hydraulic bridge solution 35 in the measurement, whereby the errors caused by the viscosity fluctuations of the fluid are reduced.

Thanks to the amplifier element (6), the frictional forces that may occur in the control opening (7) also do not affect the measuring element, so that the structural and dimensioning solutions of the control opening (7) 4 77123 can be made more versatile than previously known solutions.

Since the throttle member (1) in the regulator according to the invention may be in a fixed body part and the pressure difference 5 generated therein may be small, the regulator according to the present invention can be better applied to remote control and other variables than the regulators according to the previous inventions.

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Claims (9)

1. A self-contained flow controller that, without external auxiliary energy, adjusts the flow of liquid, vapor, or kaa-5 flowing through it independently of the pressure difference between inlet and outlet pressures to a preset value within the controller-specific range and accuracy, and includes a fixed body , formed by the measuring chamber part (9) and the control chamber part (10) and the inlet connection (14) and the outlet connection (15) located therein, characterized in that the measuring chamber part (9) has an adjustable measuring opening member (1), the membrane member (3) and the spring (2) and the control chamber part (10) have a self-powered servo amplifier formed by the spring (8), the membrane member (6) and the opening (5) therein and a position-dependent adjustment opening of the membrane member (6) (7), and that the position of the film-like measuring member (3) directly or via the spindle member (4) affects the throttling of the opening (5) and that the position of the film-like measuring member (6) follows changes in the position of the film-like measuring member (3). 2. A self-contained flow controller that, without external auxiliary energy, regulates the flow of liquid, vapor, or gas flowing through it independently of the pressure difference between inlet and outlet pressures to a preset value within the controller-specific range and accuracy, and includes 25 fixed bodies formed by the measuring chamber part (9) and the control chamber part (10) and the inlet connection (14) and the outlet connection (15) located therein, characterized in that the measuring chamber part (9) has an adjustable measuring opening member (1), membrane-like the member (3) and the spring (2) and the control chamber part 30 (10) have a self-powered servo amplifier formed by the spring (8), the membrane-like member (6) and an opening in the fixed body (not shown) and a position-dependent adjustment opening of the membrane-like member (6) (7), and that the position of the film-like measuring member (3) directly or via the spindle member (4) affects the throttling of said opening in the body, and that the position of the film-like member (6) follows the film changes in the position of the measuring element (3). Flow regulator according to Claim 1 or 2, characterized in that the body part consists of 40 combined measuring and control chambers. 6 77123 Claims 1, 2. and a flow regulator according to claim 3, characterized in that the measuring orifice member (1) is located in the membrane-like member (3). Claims 1, 2, 3. and a flow regulator according to claim 4, characterized in that the measuring orifice member is provided with a remote control. 5,771 23 Flow regulator according to Claims 1, 2, 3 and 3, characterized in that the size of the measuring opening (1) is influenced by another quantity. Claims 1, 2, 3, 4, 5. and 6. flow regulator, characterized in that it is provided with a non-return valve function. Flow regulator according to Claims 1, 2, 3, 4, 5, 6 and 7, characterized in that it is provided with a flow indicator (11 and 11.1). Claims 1, 2, 3, 4, 5, 6, 7. and 8. flow regulator, characterized in that it is provided with an alarm function. 7 77123